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Transamination diverts the excess amino acids towards energy generation. 7. The amino acids undergo transamination to finally concentrate nitrogen in glutamate.
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The amino acids undergo certain common reactions like transamination followed by deamination for the liberation of ammonia. The amino group of the amino acids is utilized for the formation of urea which is an excretory end product of protein metabolism. The carbon skeleton of the amino acids is first converted to keto acids (by transamination) which meet one or more of the following fates.
of keto acids, catalysed by a group of enzymes called transaminases (recently, aminotransferases ). Salient features of transamination
Oxidative deamination is the liberation of free ammonia from the amino group of amino acids coupled with oxidation. This takes place mostly in liver and kidney. The purpose of oxidative deamination is to provide NH 3 for urea synthesis and α-keto acids for a variety of reactions, including energy generation. Role of glutamate dehydrogenase : In the process of transamination, the amino groups of most amino acids are transferred to α-ketoglutarate to produce glutamate. Thus, glutamate serves as a ‘ collection centre ’ for amino groups in the biological system. Glutamate rapidly undergoes oxidative deamination, catalysed by glutamate dehydrogenase (GDH) to liberate ammonia. This enzyme is unique in that it can utilize either NAD+^ or NADP+^ as a coenzyme. Conversion of glutamate to α-ketoglutarate occurs through the formation of an intermediate, α-iminoglutarate ( Figure 3 ). Glutamate dehydrogenase catalysed reaction is important as it reversibly links up glutamatenmetabolism with TCA cycle through α-ketoglutarate. GDH is involved in both catabolic and anabolic reactions. Figure 3: Oxidation of glutamate by glutamate dehydrogenase (GDH). GDH is controlled by allosteric regulation. GTP and ATP inhibit —whereas GDP and ADP activate —glutamate dehydrogenase. Steroid and thyroid hormones inhibit GDH. After ingestion of a protein-rich meal, liver glutamate level is elevated. It is converted to α-ketoglutarate with liberation of NH 3. Further, when the cellular energy levels are low, the degradation of glutamate is increased to provide α-ketoglutarate which enters TCA cycle to liberate energy.
L-Amino acid oxidase and D-amino acid oxidase are flavoproteins, possessing FMN and FAD, respectively. They act on the corresponding amino acids (L or D) to produce
α-keto acids and NH 3. In this reaction, oxygen is reduced to H 2 O 2 , which is later decomposed by catalase ( Figure 4 ). Figure 4: Oxidative deamination of amino acids
Some of the amino acids can be deaminated to liberate NH 3 without undergoing oxidation (a) Amino acid dehydrases : Serine, threonine and homoserine are the hydroxy amino acids. They undergo non-oxidative deamination catalysed by PLP-dependent dehydrases (dehydratases). (b) Amino acid desulfhydrases : The sulfur amino acids, namely cysteine and homocysteine, undergo deamination coupled with desulfhydration to give keto acids. (c) Deamination of histidine: The enzyme histidase acts on histidine to liberate NH 3 by non- oxidative deamination process.